Discovering New Strong Gravitational Lenses in the DESI Legacy Imaging Surveys

Huang, Xiaosheng; Storfer, C.; Gu, A.; Ravi, Vikram; Pilon, Andrew; Sheu, W.; Venguswamy, R.; Bankda, S.; Dey, Arjun; Landriau, Martin; Lang, Dustin; Meisner, Aaron M.; Moustakas, John; Myers, Adam D.; Sajith, R.; Schlafly, Edward F.; Schlegel, David J.

doi:10.3847/1538-4357/abd62b

Cited by 70 publications

(86 citation statements)

References 80 publications

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“…Convolutional neural networks (CNNs; LeCun et al 1998) have proven extremely efficient for pattern recognition tasks and have given a strong impetus to image analysis and processing. Recent studies largely demonstrate the ability of supervised CNNs to identify the rare gravitational lenses among large datasets (e.g., Jacobs et al 2017Jacobs et al , 2019Petrillo et al 2019;Huang et al 2021), extending previous automated algorithms (e.g., Gavazzi et al 2014;Joseph et al 2014) generally with better classification performance (Metcalf et al 2019). In Cañameras et al (2020, hereafter C20), we show that realistic simulations and careful selection of negative examples are crucial for successfully conducting a systematic search over 30 000 deg 2 with PanSTARRS multiband imaging.…”

Section: Introductionsupporting

confidence: 63%

“…In the recent past, Lanusse et al (2018) have developed ResNet architectures for lens finding on LSSTlike simulations, and obtained better results than classical CNNs on the strong lens finding challenge (Metcalf et al 2019). Subsequent studies confirm that such ResNets can efficiently select lenses on real survey data (e.g., Li et al 2020;Huang et al 2021).…”

Section: Training the Neural Networkmentioning

confidence: 95%

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Holismokes

Cañameras

Schuldt

Shu

et al. 2021

A&A

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We have carried out a systematic search for galaxy-scale strong lenses in multiband imaging from the Hyper Suprime-Cam (HSC) survey. Our automated pipeline, based on realistic strong-lens simulations, deep neural network classification, and visual inspection, is aimed at efficiently selecting systems with wide image separations (Einstein radii θE ∼ 1.0–3.0″), intermediate redshift lenses (z ∼ 0.4–0.7), and bright arcs for galaxy evolution and cosmology. We classified gri images of all 62.5 million galaxies in HSC Wide with i-band Kron radius ≥0.8″ to avoid strict preselections and to prepare for the upcoming era of deep, wide-scale imaging surveys with Euclid and Rubin Observatory. We obtained 206 newly-discovered candidates classified as definite or probable lenses with either spatially-resolved multiple images or extended, distorted arcs. In addition, we found 88 high-quality candidates that were assigned lower confidence in previous HSC searches, and we recovered 173 known systems in the literature. These results demonstrate that, aided by limited human input, deep learning pipelines with false positive rates as low as ≃0.01% can be very powerful tools for identifying the rare strong lenses from large catalogs, and can also largely extend the samples found by traditional algorithms. We provide a ranked list of candidates for future spectroscopic confirmation.

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Section: Introductionsupporting

confidence: 63%

Section: Training the Neural Networkmentioning

confidence: 95%

Holismokes

Cañameras

Schuldt

Shu

et al. 2021

A&A

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“…In the future, new tools will expedite the current manual process of SL analysis. Examples include the introduction of convolutional neural networks for identification of SL features (e.g., Petrillo et al 2017;Jacobs et al 2019;Cañameras et al 2020;Huang et al 2021) and machine-learning algorithms to model the mass distribution of strong lenses (e.g., Bom et al 2019;Pearson et al 2019). We look forward to the continuous development of these tools, as the SHMs introduced in this work will greatly benefit from them.…”

Section: Discussionmentioning

confidence: 99%

Core Mass Estimates in Strong Lensing Galaxy Clusters Using a Single-halo Lens Model

González

Sharon

et al. 2021

ApJ

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The core mass of galaxy clusters is an important probe of structure formation. Here we evaluate the use of a single-halo model (SHM) as an efficient method to estimate the strong lensing cluster core mass, testing it with ray-traced images from the Outer Rim simulation. Unlike detailed lens models, the SHM represents the cluster mass distribution with a single halo and can be automatically generated from the measured lensing constraints. We find that the projected core mass estimated with this method, M SHM, has a scatter of 8.52% and a bias of 0.90% compared to the “true” mass within the same aperture. Our analysis shows no systematic correlation between the scatter or bias and the lens-source system properties. The bias and scatter can be reduced to 3.26% and 0.34%, respectively, by excluding models that fail a visual inspection test. We find that the SHM success depends on the lensing geometry, with single giant arc configurations accounting for most of the failed cases due to their limiting constraining power. When excluding such cases, we measure a scatter and bias of 3.88% and 0.84%, respectively. Finally, we find that when the source redshift is unknown, the model-predicted redshifts are overestimated, and the M SHM is underestimated by a few percent, highlighting the importance of securing spectroscopic redshifts of background sources. Our analysis provides a quantitative characterization of M SHM, enabling its efficient use as a tool to estimate the strong lensing cluster core masses in the large samples, expected from current and future surveys.

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“…Além disso conforme o volume de dados disponíveis cresce esse tipo de abordagem se torna ineficiente para análise massiva de dados. Uma alternativa a inspeção visualé o desenvolvimento de métodos computacionais de busca de sistemas de lentes automatizadas por Aprendizado de Máquina (ou Machine Learning) e Deep Learning [24,25,43,[67][68][69][70], sendo esté ultimo um ramo do Machine Learning que dispõe de redes com um grande número de camadas e parâmetros, tipicamente utilizando requerendo uso intensivo e computação e GPUs e [71]. Métodos de Deep Learning, e especificamente um subtipo, as Redes Neurais Convolucionais (da sigla em inglês CNNs) são consideradas o estado-da-arte do reconhecimento de padrões em imagens e, portanto particularmente interessantes na busca de efeito forte de lente em imagens de galáxias.…”

Section: Busca De Lentes Gravitacionaisunclassified

Desenvolvendo um Ensemble de Redes Profundas para identificação de Lentes Gravitacionais: Aplicação em Regime de Poucos dados

Castro¹,

Teles²,

Escovedo³

2021

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Resumo: O treinamento de redes neurais profundas com pequenos conjuntos de dadosé um desafio em diversos casos. Isso pode ocorrer quando o fenômeno de interesseé imprevisível ou extremamente raro. Neste trabalho, analisamos o desempenho da classificação realizada pelas redes profundas ResNet 50, EfficientNet B2 e do Ensemble entre elas. O conjunto de dados utilizadoé um banco de imagens simuladas de um fenômeno físico bastante raro: o lenteamento gravitacional. Foram feitos ajustes nos modelos, com o objetivo de obter o melhor desempenho com o menor conjunto de dados de treinamento. Testamos os modelos com diferentes quantidades de dados, analisando o desempenho de cada um a partir da métrica AUC (área sob a curva ROC). O melhor desempenho em um conjunto restrito a 80 imagens de treino foi obtido através de um ensemble dos dois modelos de redes neurais profundas com uma AUC 0,796.

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Discovering New Strong Gravitational Lenses in the DESI Legacy Imaging Surveys

Cited by 70 publications

References 80 publications

Holismokes

Holismokes

Core Mass Estimates in Strong Lensing Galaxy Clusters Using a Single-halo Lens Model

Desenvolvendo um Ensemble de Redes Profundas para identificação de Lentes Gravitacionais: Aplicação em Regime de Poucos dados

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